Clinical Trial Details
— Status: Terminated
Administrative data
| NCT number |
NCT03513042 |
| Other study ID # |
NL63825.058.17 |
| Secondary ID |
916.18.008P17.29 |
| Status |
Terminated |
| Phase |
|
| First received |
|
| Last updated |
|
| Start date |
January 21, 2021 |
| Est. completion date |
November 23, 2022 |
Study information
| Verified date |
December 2022 |
| Source |
Leiden University Medical Center |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Observational
|
Clinical Trial Summary
The goal of this project is to develop and characterise an imaging strategy for
biology-guided individualisation of the proton therapy plan to improve patient outcome and
quality-of-life.
Positron-emission tomography (PET) studies reflecting glucose metabolism, hypoxia and
physical changes of proton-irradiated tumour tissues will be performed. Patients with head
and neck cancer will be studied, as these individuals frequently experience recurrences
within the radiation field, often with limited therapeutic options. Severe side-effects and
functional impairment, deteriorating patients' quality-of-life, limited the use of
dose-escalation in recent feasibility studies of photon therapy guided by individual
PET-response. However, proton therapy, currently being introduced in the Netherlands,
improves the precision of radiotherapy and thereby limits the side-effects caused by
irradiation of neighbouring healthy tissues. Therefore, in proton therapy dose-escalation to
improve patient outcome is less restricted by toxicity.
Using PET-studies of two hallmarks of radioresistance, glucose metabolism and hypoxia,
side-by-side, before and early in-treatment, the predictive ability of both PET-techniques
for local recurrence-free survival will be compared. A treatment plan adapted to the
individual response measured by both procedures and compute tumour-dose and toxicity, will be
simulated, thereby substantiating feasibility of image-guided adaptive replanning.
Simultaneously to biological responses, proton therapy-induced physical changes will be
studied. These atomic changes, dependent on tissue-composition and dose-deposition, are
measurable by PET. It is expected that activation-PET to measure tissue-changes during
therapy, a potential new biomarker of treatment efficacy, toxicity but also accuracy of
treatment plan execution. Activation-PET will be related to earlier-mentioned PET-imaging of
metabolism.
This clinical-technological project paves the way for an interventional trial of PET-guided
treatment personalisation. Activation-PET will also serve as biomarker and quality control
for proton therapy and support the current development of specialised in-beam PET-technology.
These PET-techniques together will help us to individualise treatment, which is of great
importance for the success and cost-effectiveness of proton therapy.
Description:
Rationale: Proton therapy (PT), currently being introduced in the Netherlands, delivers
radiation dose more conformal than photon radiotherapy, therefore healthy tissue damage is
expected to be lower and at least similar tumouricidal effects are described. This increases
the therapeutic window of radiotherapy which could be used for intensified treatment to
patients prone to locoregional failure. From photon radiotherapy it is known that
stratification of patients with head and neck squamous cell carcinoma (HNSCC) is possible
using different positron-emission tomography (PET-)techniques. Distribution of tumour
hypoxia, a main cause of resistance to radiotherapy, and glucose metabolic need have been
described. PT, in contrast to photon therapy, results in activation of endogenous atoms in
the irradiated tissues which can be measured using PET and reflect dose deposition and tissue
composition. This provides a unique application of PET in this treatment modality as quality
assurance of proton therapy and potentially as biomarker of tissue response to proton
therapy. The main hypothesis is that early during PT, PET is capable of discerning a subset
of patients with increased risk of locoregional failure with a univariate hazard-ratio of at
least 4.0. At this time point, treatment intensification would still be possible.
Objective: To assess whether early changes in hypoxia between baseline and in the (end of
the) second week of proton therapy are predictive for time-to-local recurrence in patients
with HNSCC (primary). Secondary objectives include: to compare the role of hypoxia-PET to
more readily available PET of glucose metabolism, to describe spatial conformity between the
PET-scan and the location of the recurrence, to determine the potential of adaptive
replanning based on two-timepoint PET-imaging. In a pilot setting the feasibility of
activation PET in a clinical setting for quality assurance of PT-plans and potential
biomarker of PT-induced tissue changes will be explored.
Study design: Prospective, single-arm, observational cohort study with invasive measurements.
Study population: Adults diagnosed with primary, unresected invasive HNSCC, planned for PT ±
systemic therapy with curative intent with at least one measurable lesion larger than 2 cm at
baseline (n=40).
Intervention: All patients are asked to undergo one additional baseline 18F-FAZA PET-scan
(hypoxia) at baseline 18F-FDG PET-imaging (glucose metabolism) is already performed during
clinical work-up. Both 18F-FAZA and 18F-FDG PET-scans will be repeated in the (end of the)
second week of PT, unless no hypoxia is witnessed at baseline, then only the 18F-FDG PET-scan
is repeated. In a pilot setting, 10 patients are asked to further undergo activation
PET-scanning immediately after PT in the first, second and last week.
Main study parameters/endpoints: The main study parameters are the percent change in hypoxic
tumour volume between baseline PET and interim PET of hypoxia and the percent change in total
lesion glycolysis between baseline PET and interim PET of glucose metabolism. The primary
endpoint is 3-year local recurrence-free survival (LRFS).
Nature and extent of the burden and risks associated with participation, benefit and group
relatedness: Each PET-acquisition will be performed in radiotherapy position preferably using
fixation devices (mould mask). The procedures of PET-imaging of 18F-FAZA (hypoxia) and
18F-FDG (glucose metabolism) each involve preparation (hypoxia: none, glucose metabolism: 6h
fasted), intravenous injection of a radiopharmaceutical, a waiting period in solitude
(hypoxia: 2 h, glucose metabolism: 1 h), followed by PET-acquisition (hypoxia: 10-20 min,
glucose metabolism: 5-10 min). Occurrence of infusion-related reactions (e.g. allergy) is
highly unlikely. The radiation burden attached to each of these procedures are 6.8 mSv
(hypoxia) and 2.9 mSv (glucose metabolism). The pilot substudy requires immediate transfer
from PT-gantry to scanner followed by a 30-min PET-acquisition three times, resulting in an
additional radiation burden of ~0.5 mSv per procedure. All other procedures are part of
clinical protocol. There will be no individual benefit for enrolled subjects. Financial
compensation for study-related travel expenses have been arranged. However, where possible,
each study procedure will be combined with a regular visit to the PT-facility.
